TWI709019B - Core for inductance, core body for electronic pen, electronic pen and input device - Google Patents

Abstract

The inductor core of the present invention includes a cylindrical magnetic body 10 made of a magnetic body. The magnetic body 10 has an inclined portion 11 having an outer diameter that increases from one end 10a of the magnetic body 10 toward the other end 10b. The inclined surface 11a of the circumferential surface of the truncated cone; the straight body portion 12, which is located coaxially with the inclined portion 11, and has an outer circumferential surface 12a extending from the other end 10b toward one end 10a and forming a cylindrical body; and a flange The portion 13, which is located between the inclined portion 11 and the straight body portion 12, and connects the inclined portion 11 and the straight body portion 12; the outer peripheral surface 13a of the flange portion 13 has a larger outer diameter than the inclined portion 11 and the straight body portion 12 Outer diameter.

Description

Core for inductance, core body for electronic pen, electronic pen and input device

The invention relates to a core for inductance, a core body for an electronic pen, an electronic pen and an input device.

To detect the position in tablet computers and displays equipped with position detection sensors, and input the position information into input devices such as PC (Personal Computer) and smart phones, in order to indicate the position detection sensor Position on the device, and use an electronic pen.

The position detection device can be used for detection by using a coupling method such as electromagnetic induction coupling or electrostatic induction coupling between the position detection sensor and the electronic pen to perform position detection signals (for example, Patent Document 1).

The electronic pen used in this type of input device has an inductor core formed by arranging a magnetic body such as ferrite around the core of the electronic pen. [Prior Technical Literature] [Patent Literature]

[Patent Document 1] International Publication No. 2017/183526

[Technical means to solve the problem]

The inductor core of the present invention includes a cylindrical magnetic body made of a magnetic body. The magnetic body has: an inclined portion having a circumference whose outer diameter increases from one end of the magnetic body toward the other end and forms a truncated cone The inclined surface of the surface; the straight body portion, which is located coaxially with the inclined portion, and has an outer peripheral surface extending from the other end toward the one end and forming the peripheral surface of the cylindrical body; and the flange portion, which is located on the inclined portion And the straight body part, and connect the inclined part and the straight body part; the outer peripheral surface of the flange part has an outer diameter larger than the outer diameters of the inclined part and the straight body part.

The core part for an electronic pen of the present invention includes: the above-mentioned core for inductance; and a core body which is inserted into the above-mentioned core for inductance and arranged so that the tip part protrudes from one end of the above-mentioned core for inductance.

The electronic pen of the present invention includes: a casing having an opening; and the core portion for the electronic pen; the core portion for the electronic pen is housed in the casing, and the tip portion of the core portion for the electronic pen The way in which the opening of the above-mentioned housing protrudes or can be arranged protrudingly.

The input device of the present invention includes the above-mentioned electronic pen, and a position detection device having a sensor that detects the position approached by the above-mentioned electronic pen.

Hereinafter, referring to the drawings, the core for inductance, the core body for electronic pen, the electronic pen, and the input device of the present invention will be described in detail. Fig. 1 is a plan view showing an example of the inductor core of the first embodiment. In addition, FIG. 2 is a cross-sectional view showing an example of the inductor core of the first embodiment. The inductor core 1 includes a magnetic body 10 made of a magnetic body such as a ferrite sintered body.

The inductor core 1 includes a cylindrical magnetic body 10 and has a cylindrical cylindrical hole 10c penetrating from one end 10a to the other end 10b. The magnetic body 10 includes: an inclined portion 11 having an inclined surface 11a whose outer diameter increases from one end 10a to the other end 10b and forming a circumferential surface of a truncated cone; a straight body portion 12 is formed on the same axis as the inclined portion 11 The outer peripheral surface 12a of the cylindrical body extending from the other end 10b to the one end 10a; and the flange portion 13, which is located between the inclined portion 11 and the straight body portion 12 and connects the inclined portion 11 and the straight body portion 12. The inclined portion 11, the flange portion 13, and the straight body portion 12 are arranged in sequence from one end 10a to the other end 10b. The outer peripheral surface 13a of the flange portion 13 has an inclined surface 11a larger than the inclined portion 11 and an outer peripheral surface 12a of the straight body portion 12 The outer diameter of each outer diameter.

The length from one end 10a to the other end 10b of the magnetic body 10 is, for example, about 5 mm to 15 mm, and the diameter of the cylindrical hole 10c is about 0.5 mm to 2.0 mm. The length of the straight body 12 is about 3 mm~12 mm, and the outer diameter of the straight body 12 is about 2.0 mm~3.0 mm. The length of the inclined part 11 is about 0.5 mm~2.0 mm, the outer diameter of one end 10a side of the inclined part 11 is about 1 mm~2 mm, and the outer diameter of the inclined part 11 opposite to the end 10a is the same as the straight body part 12. The outer diameter is roughly the same. In this way, the inclined portion 11 has a shape with a tapered tip toward one end 10a.

The flange portion 13 may also be located between the inclined portion 11 and the straight body portion 12 of the magnetic body 10, connect the inclined portion 11 and the straight body portion 12, and have a first curved outer peripheral surface 13a. The outer circumferential surface 13a may also be a curved surface that is convexly curved toward the outside in the radial direction, and the maximum outer diameter of the outer circumferential surface 13a is larger than the outer diameters of the inclined portion 11 and the straight body portion 12. For example, when the outer diameter of the straight body 12 is 2.1 mm~2.5 mm, the maximum outer diameter of the outer peripheral surface 13a is 2.12 mm~2.72 mm, and the maximum protrusion from the outer peripheral surface 12a of the straight body 12 is 0.02 mm~ 0.22 mm.

The inductor core 1 of such a shape is used by inserting the following core body into the cylindrical hole 10c. The core system is inserted so that the front end of the core becomes the side of one end 10a of the magnetic body 10. Since the inclined portion 11 has a tapered shape, one end 10a of the magnetic body 10 can be brought closer to a position detection device such as a tablet computer that detects the position by electromagnetic induction. In this way, by setting the inclined portion 11 of the magnetic body 10 into a tapered shape, the position detection accuracy of the position detection device is improved. However, the front end of the magnetic body 10 is tapered, so the strength of the magnetic body 10 is obtained. Worries about shortcomings and deformation. However, the flange portion 13 has a portion having an outer diameter larger than that of the inclined portion 11 and the straight body portion 12. Compared with the shape of the flange-less portion 13 in which the inclined portion 11 and the straight body portion 12 are directly connected, the magnetic body 10 is The rigidity is relatively high, so a highly reliable inductor core 1 can be provided.

In the cross section of the magnetic body 10 along the central axis, the outer diameter of the inclined portion 11 increases from one end 10a toward the other end 10b. That is, the inclined portion 11 has a shape whose tip is tapered toward one end 10a. Such an inclined surface 11a may include the inclined surface 11a1 which is a linear part and the inclined surface 11a2 with an arc in a cross-sectional view. At this time, the inclined surface 11a1 may also form the circumferential surface of the truncated cone. In addition, the inclined surface 11a2 near one end 10a may be a convex curved surface. In this configuration, the inclined surface 11a1 of the inclined portion 11 and the end surface 11b of the inclined portion 11 are connected by the inclined surface 11a2 which is a part of the inclined surface 11a and is a convex second curved surface.

In this way, when the inclined surface 11a1 and the end surface 11b are connected by the inclined surface 11a2 which is a convex curved surface, for example, when the end surface 11b of the inclined portion 11 contacts the housing of the electronic pen, the possibility of damage can be reduced. Moreover, when the electronic pen is placed down and brought into contact with the surface of a tablet computer, etc., in addition to the core, the front end including one end 10a of the magnetic body 10 may also contact the tablet computer, etc., but because The inclined surface 11a1 and the end surface 11b of the inclined portion 11 are connected by the inclined surface 11a2, which is a convex curved surface, and therefore has no corners. Therefore, it is possible to reduce the risk of damage to the surface of the tablet computer and the like due to the inductor core 1.

In the inner peripheral surface 10e of the cylindrical hole 10c of the magnetic body 10, the inner peripheral surface 10e near the opening 10d on the side of the inclined portion 11 may also have an arc. The inner circumferential surface 10e may also include an inner circumferential surface 10e1, and an inner circumferential surface 10e2 connecting the inner circumferential surface 10e1 and the end surface 11b of the inclined portion 11 and being a convex third curved surface. When the inner surface of the cylindrical hole 10c and the end surface 11b of the inclined portion 11 are connected by the inner peripheral surface 10e2 of a convex curved surface, when the core is pressed against the surface of a tablet computer, etc., the concentration of stress can be suppressed. In addition, the possibility of damage to the magnetic body 10 is reduced, so that a highly reliable inductor core 1 can be realized.

In addition, in the cross section of the magnetic body 10 along the central axis, the curvature radius of the inclined surface 11a2 connecting the inclined surface 11a1 of the inclined portion 11 and the end surface 11b of the inclined portion 11 is R1, and the connecting cylindrical hole 10c When the radius of curvature of the inner circumferential surface 10e1 and the inner circumferential surface 10e2 of the end surface 11b of the inclined portion 11 is set to R2, the radius of curvature R1 of the inclined surface 11a2 may also be greater than the radius of curvature R2 of the inner circumferential surface 10e2. The curvature radius R1 of the inclined surface 11a2 is, for example, 0.1 mm to 0.2 mm, and the curvature radius R2 of the inner peripheral surface 10e2 is, for example, 0.02 mm to 0.08 mm.

3 is a partial plan view showing an example of the inductor core of the second embodiment, and FIG. 4 is a partial cross-sectional view showing an example of the inductor core of the second embodiment. The inductor core 1 of the second embodiment is different from the inductor core 1 of the first embodiment in the form of the flange portion 13. In the second embodiment, the outer peripheral surface 13a of the flange portion 13 is configured by combining the outer peripheral surface 13a1 as the first curved surface, the outer peripheral surface 13a2 as the first connecting surface, and the outer peripheral surface 13a3 as the second connecting surface. The outer peripheral surface 13a1 is a curved surface that is convexly curved outward in the radial direction, and the outer peripheral surface 13a2 is a surface connecting the edge end P2 on the side of one end 10a of the outer peripheral surface 13a1 and the edge end P1 on the other end 10b side of the inclined surface 11a. In addition, the outer peripheral surface 13a3 is a surface connecting the edge end P3 on the other end 10b side of the outer peripheral surface 13a1 and the edge end P4 on the one end 10a side of the outer peripheral surface 12a of the straight body portion 12. The outer peripheral surface 13a2 is inclined such that the outer diameter becomes larger from the edge end P1 on the other end 10b side of the inclined surface 11a toward the edge end P2 on the one end 10a side of the outer peripheral surface 13a1, and the outer peripheral surface 13a3 is a self-straight body 12 The edge end P4 on the one end 10a side of the outer peripheral surface 12a is inclined so that the outer diameter of the edge end P3 on the other end 10b side of the outer peripheral surface 13a1 becomes larger.

Since the flange portion 13 having the outer circumferential surface 13a1, the outer circumferential surface 13a2, and the outer circumferential surface 13a3 has a part whose outer diameter is larger than that of the inclined portion 11 and the straight body portion 12, it is directly connected to the inclined portion 11 and the straight body portion 12 Compared with the shape of the flangeless portion 13, the strength of the magnetic body 10 is higher, and therefore the reliability of the inductor core 1 can be improved.

In addition, the magnetic body 10 is composed of a ceramic mainly composed of ferrite containing oxides of Fe, Zn, Ni, and Cu, and the coefficient of variation CV of the average crystal grain size of the ceramic is represented by the following formula (1) It may also be 0.08 or more and 0.3 or less. CV=σ/x (1) among them, x is the average value of the average crystal grain size of the above ceramics, σ is the standard deviation of the average crystal grain size of the above-mentioned ceramics.

If the coefficient of variation CV is 0.08 or more, the grain size of the crystal grains is appropriately uneven, and the smaller crystal grains are arranged between the larger crystal grains, so that the fracture toughness can be improved. If the coefficient of variation CV is 0.3 or less, the ratio of crystal grains with a diameter larger than the standard deviation increases, and therefore the magnetic permeability becomes higher. As long as the coefficient of variation CV is 0.08 or more and 0.3 or less, it can have both higher fracture toughness and higher magnetic permeability.

In particular, the coefficient of variation CV is preferably 0.1 or more and 0.2 or less.

Here, the average crystal grain size can be obtained as follows.

Firstly, the fracture surface of the inductor core 1 is polished in a copper plate with diamond abrasive grains with an average particle size D ₅₀ of 3 μm, and then, in a tin plate using diamond abrasive grains with an average particle size D ₅₀ of 0.5 μm . Regarding the polished surface obtained by the polishing, the temperature was set to 950° C., and the etching was performed until the crystal grains and the grain boundary layer were recognized to obtain an observation surface.

The average crystal grain size can be obtained by the following method, that is, within a range of 155 μm×115 μm obtained by using a scanning electron microscope to magnify the observation surface to 5000 times, 6 strips are drawn radially around an arbitrary point For a straight line of the same length, for example 100 μm, divide the length of the 6 straight lines by the number of crystals existing on each straight line.

Figure 8 is a photograph showing an example of the observation surface of the inductor core and the method of drawing straight lines. The straight line A to the straight line F shown in Fig. 8 are each a straight line with a length of 100 μm, and the average crystal grain size can be obtained using these straight lines. The average value, standard deviation, and coefficient of variation CV of the average crystal grain size can be calculated by selecting 7 screens for such an observation surface and using 42 average crystal grain sizes as objects.

In addition, the kurtosis Ku of the average crystal grain size may be 0 or more.

If the kurtosis Ku of the average crystal grain size is in this range, the unevenness of the grain size is suppressed, so the aggregation of pores is reduced, and the outline of the pores or the degranulation generated inside can be reduced. In particular, the kurtosis Ku of the average crystal grain size is preferably 1 or more.

Here, the so-called kurtosis Ku is an index (statistic) indicating the degree of difference between the peak and foot of the distribution and the normal distribution. When kurtosis Ku>0, it is a distribution with sharp peaks. In kurtosis Ku In the case of =0, it is a normal distribution, and in the case of kurtosis Ku<0, the distribution becomes a distribution with a peak with an arc.

The kurtosis Ku of the average crystal grain size can be obtained using the function Kurt provided in Excel (registered trademark, Microsoft Corporation).

In addition, the skewness Sk of the average crystal grain size may be 0 or more.

If the skewness Sk of the average crystal grain size is in this range, the grain size distribution of the crystal grains moves toward the smaller grain size, so the agglomeration of pores is reduced, which can further reduce the outline of the pores or the threshing generated inside .

Here, the so-called skewness Sk refers to the degree to which the distribution is skewed compared to the normal distribution, that is, an index (statistic) of the symmetry of the distribution. When the skewness Sk>0, the foot of the distribution is directed On the right, when the skewness Sk=0, the distribution is symmetrical, and when the skewness Sk<0, the foot of the distribution is toward the left.

The skewness Sk of the average crystal grain size can be calculated using the function SKEW provided in Excel (registered trademark, Microsoft Corporation).

At least the inclined portion 11 contains Mo, and Mo may be more contained in the grain boundary layer than in the crystal grain.

If Mo is contained in the grain boundary layer more than in the crystal grains, the coupling force between the crystal grains mainly composed of ferrite is suppressed, and therefore the inclined surface 11a2 with a large curvature radius R1 can be easily obtained .

The content of Mo in the crystal grain and in the grain boundary layer can be analyzed using a transmission electron microscope and an energy dispersive X-ray spectrometer (EDS) attached to the transmission electron microscope.

The magnetic body 10 used in the inductor core 1 can be manufactured as follows. First, as starting materials, oxides of Fe, Zn, Ni, and Cu or metal salts such as carbonates and nitrates that are produced by firing are prepared. At this time, as the average particle size, for example, when Fe is iron oxide (Fe ₂ O ₃ ), Zn is zinc oxide (ZnO), Ni is nickel oxide (NiO), and Cu is copper oxide (CuO), each is 0.5 μm. Above 5 μm.

Then, when the first raw material composed of the calcined powder containing Fe ₂ O ₃ -ZnO-NiO and the second raw material composed of the calcined powder containing Fe ₂ O ₃ -CuO are produced, the required amount is weighed The iron oxide, zinc oxide and nickel oxide are used as the first raw material. In addition, required amounts of iron oxide and copper oxide are weighed as the second raw material. Here, regarding the amount of iron oxide added in the production of the first raw material and the second raw material, the amount of iron oxide added in the production of the second raw material is set to, for example, mole% with copper oxide, and the remaining amount is used For the production of the first raw material.

Then, the powders weighed to be used as the first raw material and the second raw material are pulverized and mixed by different ball mills or vibration mills, etc., and then calcined at 750°C in a reducing atmosphere during the production of the first raw material 2 When the second raw material is produced, it is calcined at 650°C for 2 hours or more in a reducing atmosphere to obtain calcined bodies.

Next, the calcined bodies that become the first raw material and the second raw material are put into different ball mills, vibrating mills, etc., and pulverized to obtain the first raw material and the second raw material composed of calcined powder. At this time, in particular, the calcining system used as the second raw material is pulverized so that the average particle diameter D50 becomes 0.7 μm or less. Then, after weighing and mixing the required amount of the first raw material and the second raw material, they are recalcined in the atmosphere at a temperature of 600°C or more and 700°C or less and a heating rate of 100°C/h or less. A calcined body synthesized as a ferrite containing oxides of Fe, Zn, Ni, and Cu is obtained.

Next, the calcined body obtained by recalcining is put into a ball mill or a vibrating mill, etc. to be pulverized, and a specific amount of binder is added to form a slurry, and the slurry is sprayed using a spray dryer By spraying and granulating, spherical particles are obtained.

Here, at least the inclined portion 11 contains Mo, and when Mo is obtained in the case of obtaining the inductor core 1 that is more contained in the grain boundary layer than in the crystal grains, it should only be compared with the calcined body obtained by recalcining 100 parts by mass, for example, 0.01 part by mass or more and 0.03 parts by mass or less of molybdenum oxide (MoO ₃ ) powder is added to prepare a slurry, and the slurry is sprayed and granulated to obtain spherical particles. can.

Then, the obtained spherical particles are used for compression molding to obtain a molded body of a specific shape. After that, the formed body is subjected to degreasing treatment in a degreasing furnace at a temperature of 400 to 800°C to form a degreased body, and then it is kept in a firing furnace at a maximum temperature of 1000 to 1200°C for 2 to 5 hours. By firing, the magnetic body 10 can be formed, and the inductor core 1 of this embodiment can be obtained.

The inclined portion 11, the straight body portion 12, and the flange portion 13 of the magnetic body 10 of the present embodiment are formed by press forming, and there is no need to perform steps such as cutting, so that cost reduction can be achieved. In addition, if subsequent processing such as cutting is performed, the surface may be deteriorated due to the subsequent processing, thereby impairing the characteristics of the inductor core. However, the inductor core 1 of this embodiment is not processed after firing, so the surface does not deteriorate. . Thereby, a highly reliable inductor core 1 can be formed.

Fig. 5 is a plan view showing an example of the core portion of the electronic pen of the present embodiment. The core part 2 for an electronic pen includes: an inductor core 1; a coil 21 wound around the magnetic body 10 of the inductor core 1; and a core 22 inserted into the cylindrical hole 10c of the magnetic body 10. The core part 2 for such an electronic pen can be built into an electronic pen of an input device such as an electromagnetic induction type tablet computer.

The core 22 can be made of metal rods such as SUS304 or SUS316 that are not easily magnetized, metal materials other than SUS, ceramics, and resins. In addition, the core body 22 may be one that can actually write, such as the core of a ballpoint pen. The core 22 is inserted into the cylindrical hole 10c of the magnetic body 10 and fixed. The front end 22a of the core 22 is fixed to the magnetic body 10 at a position protruding from the opening 10d on the side of one end 10a of the magnetic body 10 by about 1 to 2 mm. The magnetic body 10 has a shape in which the front end is tapered toward the front end 22 a of the core 22. In addition, the rear end 22b of the core 22 protrudes from the opening 10f of the other end 10b of the magnetic body 10.

A coil 21 formed by winding an enamel wire or the like is arranged on the outer peripheral surface 12a of the straight body portion 12 of the magnetic body 10 near the other end 10b. The coil 21 is wound around the straight body portion 12 of the magnetic body 10 with a width of approximately 8 mm to 12 mm, and is fixed at a position close to the other end side. The terminals 21a and 21b of the coil 21 are connected to a circuit board (not shown).

When the core part 2 for an electronic pen is brought into contact with the surface of a position detection device such as a tablet computer, force is applied from the core 22 to the magnetic body 10, but the maximum outer diameter of the flange part 13 is larger than that of the inclined part 11 and the straight part. The maximum value of the radius of the outer circumference of the body 12 makes the magnetic body 10 less likely to be damaged. Therefore, the core body 2 for an electronic pen with high reliability can be realized.

Fig. 6 is a plan view showing the electronic pen of this embodiment. A part of the housing 31 of the electronic pen 3 is removed and shown. The electronic pen core part 2 is housed in the housing 31 to constitute the electronic pen 3. The electronic pen 3 is configured by accommodating the core portion 2 for the electronic pen and the circuit board (not shown) in the cavity portion 31a of the cylindrical casing 31. Such an electronic pen 3 can be used as a component for inputting a position in an input device such as an electromagnetic induction type tablet computer. The front end 31b of the housing 31 is provided with an opening 31c through which the front end 22a of the core 22 can protrude, and the front end 22a can be protruded from the opening 31c or received in the housing 31 by a pressing mechanism.

For example, an opening 31e is provided at the rear end 31d of the housing 31, and the push rod 32 protrudes from the opening 31e. The user can push down the push rod 32 so that the front end 22 a of the core 22 enters and exits from the housing 31. Although the front end 22a of the core 22 enters and exits from the opening 31c in this embodiment, the front end 22a of the core 22 can also be fixed in a state where the front end 22a protrudes from the opening 31c. In this case, no pressing mechanism is required.

Since the front end 31b of the housing 31 is tapered, the outer periphery of the magnetic body 10 may be in contact with the inner surface of the housing 31. In this case, the inclined portion 11 is inclined and the flange 13 has a convex shape. Since the outer peripheral surface 13a is shaped like a shape, the possibility of damage to the magnetic body 10 can be reduced, and therefore the electronic pen 3 with high reliability can be realized.

Fig. 7 is a perspective view showing the input device of this embodiment. The input device 4 includes an electronic pen 3 and a tablet computer 41 as a position detection device with a sensor for detecting the position. The input device 4 can detect the position where the front end 22 a of the core 22 contacts the tablet computer 41. As the position detection device, in addition to the tablet computer 41, a mobile terminal with a touch panel display or the like may also be used. As the position detection method in the input device 4, an electromagnetic induction method can be used.

For example, even if the shape is tapered toward one end 10a of the inclined portion 11 of the magnetic body 10, and it is configured such that one end 10a of the magnetic body 10 built in the electronic pen 3 is close to the tablet computer 41, it is not easy to use The magnetic body 10 is damaged, and the surface of the tablet computer 41 is not easily damaged due to the magnetic body 10, so the input device 4 with high reliability can be realized.

The present invention can be implemented in various other forms without departing from its spirit or main characteristics. Therefore, all aspects of the above-mentioned embodiments are only examples, and the scope of the present invention is shown in the scope of the patent application, and is not limited in any way by the text of the specification. Furthermore, all changes or modifications belonging to the scope of the patent application fall within the scope of the present invention. For example, the invention produced by the combination of the embodiments of the present invention is also within the scope of the present invention.

1‧‧‧Core for inductor 2‧‧‧Electronic pen core body 3‧‧‧Electronic pen 4‧‧‧Input device 10‧‧‧Magnetic body 10a‧‧‧one end 10b‧‧‧the other end 10c‧‧‧Cylinder hole 10d‧‧‧Open 10e‧‧‧Inner peripheral surface 10e1‧‧‧Inner peripheral surface 10e2‧‧‧Inner peripheral surface 10f‧‧‧Opening 11‧‧‧Tilt 11a‧‧‧inclined surface 11a1‧‧‧inclined surface 11a2‧‧‧inclined surface 11b‧‧‧end face 12‧‧‧Straight body 12a‧‧‧Outer peripheral surface 13‧‧‧Flange 13a‧‧‧Outer peripheral surface 13a1‧‧‧Outer peripheral surface 13a2‧‧‧Outer peripheral surface 13a3‧‧‧Outer peripheral surface 21‧‧‧Coil 21a, 21b‧‧‧Terminal 22‧‧‧Core 22a‧‧‧Front end 22b‧‧‧Back end 31‧‧‧Shell 31a‧‧‧cavity 31b‧‧‧Front end 31c‧‧‧Open 31d‧‧‧Back end 31e‧‧‧Open 32‧‧‧Push stick 41‧‧‧Tablet PC A~F‧‧‧Straight P1‧‧‧Edge end P2‧‧‧Edge end P3‧‧‧Edge end P4‧‧‧Edge end R1‧‧‧Radius of curvature R2‧‧‧Radius of curvature

The purpose, features, and advantages of the present invention can be made clearer based on the following detailed description and drawings. Fig. 1 is a plan view showing an example of the inductor core of the first embodiment. Fig. 2 is a partial cross-sectional view showing an example of the inductor core of the first embodiment. Fig. 3 is a partial plan view showing an example of the inductor core of the second embodiment. Fig. 4 is a partial cross-sectional view showing an example of the inductor core of the second embodiment. Fig. 5 is a plan view showing an example of the core portion of the electronic pen of the present embodiment. Fig. 6 is a plan view showing an example of the electronic pen of this embodiment. Fig. 7 is a perspective view showing an example of the input device of this embodiment. Figure 8 is a photograph showing an example of the observation surface of the inductor core and the method of drawing straight lines.

1‧‧‧Core for inductor

10‧‧‧Magnetic body

10a‧‧‧one end

10b‧‧‧the other end

10c‧‧‧Cylinder hole

10d‧‧‧Open

10e‧‧‧Inner peripheral surface

11‧‧‧Tilt

11a‧‧‧inclined surface

11b‧‧‧end face

12‧‧‧Straight body

12a‧‧‧Outer peripheral surface

13‧‧‧Flange

13a‧‧‧Outer peripheral surface

Claims (11)

A core for an inductor, comprising a cylindrical magnetic body composed of a magnetic body, the magnetic body body having: an inclined portion having a circumference whose outer diameter increases from one end of the magnetic body to the other end and forming a truncated cone The inclined surface of the surface; the straight body portion, which is located coaxially with the inclined portion, and has an outer peripheral surface extending from the other end toward the one end and forming the peripheral surface of the cylindrical body; and the flange portion, which is located on the inclined portion And the straight body portion, and connects the inclined portion and the straight body portion; the outer peripheral surface of the flange portion has an outer diameter larger than the respective outer diameters of the inclined portion and the straight body portion; and the flange portion The outer peripheral surface includes: a first curved surface that is convexly curved outward in the radial direction; a first connecting surface that connects the edge end of the first curved surface on the one end side and the edge end of the inclined surface on the other end side; and The second connecting surface connects the edge end of the other end side of the first curved surface and the edge end of the one end side of the outer peripheral surface of the straight body portion; the first connecting surface is the other end of the inclined surface The edge end portion on the one end side is inclined so that the outer diameter of the edge end portion on the one end side of the first curved surface becomes larger, and the second connection surface faces the edge end portion on the one end side from the outer peripheral surface of the straight body portion The edge end of the other end side of the first curved surface is inclined such that the outer diameter becomes larger. The inductor core of claim 1, wherein the inclined surface of the inclined portion and the end surface of the inclined portion are connected by a convex second curved surface. The inductor core of claim 2, wherein the inner peripheral surface of the inclined portion and the end surface of the inclined portion are connected by a convex third curved surface, and the radius of curvature of the third curved surface is smaller than the radius of curvature of the second curved surface. A core for an inductor, comprising a cylindrical magnetic body composed of a magnetic body, the magnetic body body having: an inclined portion having a circumference whose outer diameter increases from one end of the magnetic body to the other end and forming a truncated cone The inclined surface of the surface; the straight body portion, which is located coaxially with the inclined portion, and has an outer peripheral surface extending from the other end toward the one end and forming the peripheral surface of the cylindrical body; and the flange portion, which is located on the inclined portion And the straight body part, and connect the inclined part and the straight body part; the outer peripheral surface of the flange part has an outer diameter larger than the outer diameters of the inclined part and the straight body part; and the magnetic body is made of The ceramic is composed of ferrite containing oxides of Fe, Zn, Ni and Cu as the main component, and the coefficient of variation CV of the average crystal grain size of the ceramic represented by the following formula (1) is 0.08 or more and 0.3 or less: CV= σ/x (1) where x is the average value of the average crystal grain size of the above-mentioned ceramics, and σ is the standard deviation of the average crystal grain size of the above-mentioned ceramics. Such as the inductor core of claim 4, wherein the kurtosis Ku of the average crystal grain size is 0 or more. Such as the inductor core of claim 4, wherein the skewness Sk of the average crystal grain size is 0 or more. Such as the inductor core of claim 5, wherein the skewness Sk of the average crystal grain size is 0 or more. An inductor core according to any one of claims 4 to 7, wherein at least the inclined portion contains Mo, and more Mo is contained in the grain boundary layer than in the crystal grain. A core body part for an electronic pen, comprising: the core for inductance according to any one of claims 1 to 8; and a core body, which is inserted into the core for inductance and has a tip from one end of the core for inductance Prominent way to configure. An electronic pen comprising: a housing having an opening; and a core portion for an electronic pen according to claim 9; the core portion for an electronic pen is housed in the housing, and the front end of the core portion for an electronic pen The part protrudes from the opening of the above-mentioned housing, or can be arranged protrudingly. An input device, comprising: an electronic pen as in claim 10; and a position detection device, which is provided with a sensor for detecting the position approached by the electronic pen.

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